Gas tight pipe connection of inner and outer pipe parts

ABSTRACT

A gas-tight pipe connection that has inner and outer pipe parts which when joined create a gas tight seal. The inner pipe part has a press fit surface, a stop surface, and a transition surface between the press fit surface and the stop surface. The outer pipe has an outer collar, a press fit surface, and a stop surface as well as a recess in its interior wall which extends from the press fit surface to the stop surface. When the outer pipe part is joined with the inner pipe part, the connection forms a press fit region, a stop region, and a transition region, where the transition region forms a coaxial intermediate space or hollow space.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.12/995,664, filed Jan. 26, 2011, which is a National Stage ofInternational Application No. PCT/AT2009/000219, filed May 26, 2009, andwhich claims the benefit of Austrian Patent Application No. A 894/2008,filed Jun. 3, 2008, the disclosures of which are incorporated herein byreference.

BACKGROUND OF THE INVENTION

The invention concerns a pipe connection, in particular a gas tight pipescrew connection wherein the parts in the connecting region areconnected by means of joining according to DIN 8593 by way ofcontact-pressing and insert-pressing, comprising an inner pipe part andan outer pipe part, or two inner pipe parts with an outer collar.

Pipes, mostly seamless pipes that can be formed from differentmaterials, are utilized for the conveyance of oil field- and/or gasfield products vertically and horizontally also over large distances andrequire, because of the significant demands, a high sealing quality ofthe connections during practical operation or application.

A pipe connection that has already been utilized over the long term, andrepresents essentially prior art in regard to the geometric basicconcepts, is designed in such a manner that an inner pipe part and anouter pipe part features sealing surfaces that are truncated cone shapedand abut against one another, with an inclination toward one another inthe distal direction of the inner pipe part of about 1:10, and that acttogether with stop surfaces that are truncated cone shaped and arealigned opposite the axis direction. A sealing effect can thereby beachieved by means of a mutual, axial contact-pressing (fully engaged) ofthe pipe endings for example by means of a thread connection or similar.

In order to improve the tightness or the quality of the pipe connectionin the case of the demands on the pipe lines present in the field, butalso to achieve in the case of a dismantling and reassembling of thepipe components maintenance of the sealing quality of the pipeconnections, a plurality of geometric embodiment forms have already beenproposed with particular design of the seal- and stop surfaces of theconnection. Complex sealing surface shapings are however usuallyassociated with higher expenditures for the chip-removing processing ofthe connecting regions of the pipe endings and with lowered costeffectiveness of manufacture.

The U.S. Pat. No. 7,334,821 B2 discloses a pipe connection with abarrel-shaped sealing surface of the pipe inner part that is convex incut, followed by a protruding extension with a distal stop surface.Thereby, during full engagement of the pipe connection, the presssurfaces of the pipe components are to obtain a higher conicity andachieve an improved sealing effect. The manufacturing effort for theconstruction of the complex shaped sealing regions appears however to behigh.

BRIEF SUMMARY OF THE INVENTION

Building on the essential geometric concepts of a pipe connectionaccording to prior art it is the object of the invention to indicate,while providing high cost effectiveness of the manufacturability, anovel pipe connection that effects improved usage characteristics of thepipe lines in practical field applications and is beneficial for adismantling and a reassembly of pipes.

The improved usage characteristics of the pipe lines concern inparticular the maintenance of the seal tightness of the respective pipeconnections in the case of high interior pressure as well as in the caseof high external pressure, as well as overlaying tensile-, pressure-,and bending-load of the pipe strand, whereby so-called seizing symptomsin the connecting region are minimized and a release and a renewed fullengagement of the connection is to be improved.

The posed problem is solved according to the invention by means of apipe connection of the type mentioned above in that the connection isimplemented with three regions, wherein the connecting regions comprisepress fit and stop of the pipe parts or press fit surfaces thatcooperate with the pipe parts and collar and that have a truncated coneshape and that are inclined in the end direction from the inner pipepart toward the pipe axis, and at the front comprise stop surfaces,which have a truncated cone shape and are directed counter to said pressfit surfaces and a transition from press fit and stop of the parts thatare connected is provided for said parts without contact with a coaxialintermediate space or hollow space.

The advantages achieved with the invention are, acting together,essentially an increase of the surface pressure on the press fitsurfaces and an advantageous positioning of said surfaces spaced apartfrom the stop surfaces. Associated with that is a general optimizationof the size of the local, mechanical material stress in the connectingregion and an avoidance of tension spikes in respect to the appearanceof plastic deformations and the initiation of tears in the material.

By means of extensive investigations it was determined that the sealingcharacteristics of the pipe connections according to the invention arecompletely maintained during pressures beyond the nominal and duringoverlaying tensile-, pressure-, and bending loads.

Calculations according to the FE method as well as elasticitydeterminations have established that through a geometry according to theinvention in the connecting region and namely with the implementation ofa hollow space between press fit- and stop surfaces a plurality ofadvantages is achieved.

For one, the press fit- and sealing fit surfaces are shortened orreduced by means of the hollow space at, relative to prior art, the samelongitudinal extent of the connection, which leads to higher sealingsurface pressures.

The transition that is implemented contact-free providesload-kinetically an elevated, largely homogeneous, specific surfacepressure and thereby the sealing at the press fit surfaces, wherein,because of an axial spacing apart relative to the stop surfaces, onlytolerable differences in the local surface pressure are created in thecase of a bending of the system. Overlaying tensile stresses andpressure tensions, if applicable, have only a negligible effect on thesealing of the connection because the press fit surfaces feature aslight inclination of about 1:10.

Advantageously the hollow space in the connecting region of the pipeparts acts as a greasing means pocket and improves the distribution andlowers the pressure of the grease material during the sealing assemblyof the field pipeline.

If, according to a preferred embodiment of the invention the transitionbetween the pipe parts, that is produced without contact of theconnecting region's press fit and stop, is formed by means of a coaxialrecess from the interior wall surface of the outer pipe part, optimalmechanical material stresses as well as also tension states that promotethe sealing of the connection are achieved.

During the insert-pressing of the inner pipe part into the outer pipepart in the case of a complete engagement setting of the connection,significant, primarily radially oriented forces are created in theregion of the press fit surfaces that leads in this region to anexpansion with a tangential, elastic stretching of the material of theouter pipe wall.

By means of a coaxial recess on the interior wall surface of the outerpipe part in the following transition region, and therefore a contactremoval of the pipe parts in the region up to the stop surfaces, noelastic stretchings of the outer pipe wall in the tangential directionare provided, however axially directed tensional forces act in saidregion that come to bear, by means of a press-on of the stop surface ofthe inner pipe, on those of the outer pipe and produce an elasticstretching in the axial direction.

In the connecting region local complex tension states are therebylargely reduced according to the invention, wherein according to theinvention the implementation of the transition region produces larger,elastic stretching values and assures the seal tightness of theconnection even in the case of complex demands on the pipe strand.

In an optimal way the recess in the transition region features in itscross section a corner-free profile because as a result tension spikeson the interior surface of the outer pipe part are largely avoided andthe initiation of tears and the danger of a breach is eliminated.

If the inner pipe part is implemented in a rounded manner in the regionof the transition from the distally continued press fit surface to thestop surface, then local tension spikes can be eliminated with localplastic material deformations and the cooperation of the stop surfacescan be improved. Particularly good results were achieved with an edgerounding with a radius of R_(c)=0.9 to 1.5 mm or for TUBINGS ofR_(τ)=0.2 to 0.6 mm.

It is advantageous if the coaxial recess is implemented in the outerpipe part in the cross section of the press fit surface with atransition radius of 0.5 to 1.0 mm and is shaped up to the stop surfaceedge-free. Thereby pressure tension spikes are assuredly avoided in theborder region of press fit surface and recess.

Extensive and specific investigations have revealed that the quotient ofthe length of the transition that is implemented without contact to thelength of the effective press fit should have in an optimal sense avalue of 0.4 to 1.7, preferably of 0.6 to 1.5, in order to achieveoptimal sealing conditions of a pipe connection according to theinvention.

This apparently broad value range was obtained from an inclusion of allcommon pipe diameters.

Dimensionally-related evaluations revealed that the quotient, for pipesthat are so-called casings with an outer diameter of larger than 4½inches, is optimized around 0.4 to 1.2, preferably around 0.6 to 1.0.

On the other hand, for riser or conveying pipes that feature an externaldiameter of smaller/equal 4½ inches to about 1.66 inches and lower, i.e.in the case of so-called tubings, optimized quotients of length of thetransition that is implemented without contact to the length of thepress fit were determined to be 0.9 to 1.7, preferably 1.1 to 1.5.

In order to achieve an optimal and high-value compact embodiment form ofthe pipe connection with increased seal tightness, the outer pipe partshould feature an inclination of the press fit surface of about 1:10relative to the diameter of the stop surfaces, and the stop surfaceshould feature, oriented oppositely, an angle beta of β=10° to 20°,preferably of β=about 15° relative to the axis normal.

If, as experiments have revealed, the press fit surfaces and/or the stopsurfaces feature a surface roughness of less than Ra=3.2 μm, howevermore than Ra=0.4 μm measured as a mean roughness value according to DIN4777 ISO/DIN4287/1, then a high specific pressure load is applicablewithout a so-called seizure of the press fit surfaces and a largelyunrestricted dismantling of the pipe connection is possible. It isassumed in this regard that in the depressions of the rough surfaceprofile in the upper roughness limits an optimal greasing means amountcan be positioned in order to achieve the desired properties.

Effect-related the pipe connection according to the invention can beplaced in full engagement through different means that press the pipeparts axially together. The known screw connections have proventhemselves to be advantageously effective.

BRIEF DESCRIPTION OF THE DRAWING

By means of a schematic illustration only one embodiment form of a pipeconnection according to the invention is to be represented in whatfollows.

It is shown:

FIG. 1 a pipe connection in an axial cut.

In FIG. 1 a pipe connection of an inner pipe I and an outer pipe A isshown in an axial cut.

DETAILED DESCRIPTION OF THE INVENTION

In the connecting region of the pipes the inner pipe part I features afrustoconical surface with a press fit surface 1I that are, in referenceto the pipe diameter, inclined distally at a value of 1:10. Followingthe press fit surface 1I distally a stop surface 2I is shaped that isinclined toward the pipe's longitudinal axis x at an angle β of 15° inan oppositely oriented manner and that represents a stop 2 with asealing surface on the front and the inner pipe end.

A outer pipe part A abuts in the case of a completely engaged pipe partconnection in the connecting region 1 proximal against the press fitsurface 1I of the inner pipe with the press fit surface A1.

Between the connecting region 1, which encompasses the press fitsurfaces 1I and 1A, and the region 2 with the stop surfaces of the pipeparts there is a transition region 3 provided in which a recess RA fromthe interior wall of the outer pipe A is present, a hollow space R isformed between the pipe parts I and A and the parts in this zone areplaced without contact.

In the outer pipe part A the border region between press fit surface 1Aand recess profile 3A is rounded with a radius of 0.8 mm, wherein inwhat follows the entire interior wall surface 3A of the coaxial recessRA up until the stop surface 2A is implemented in an edge-free roundedmanner.

It will be appreciated that the pipes I and A are generally cylindrical,rotated about the axis x in FIG. 1. Therefore, the connecting region 1and the stop region 2 are respective lateral surfaces of frusta of rightcircular cones, each being the rotation of the illustrated surface 1, 2about the axis x.

What is claimed is:
 1. A gas-tight pipe screw connection, comprising aconnecting region wherein parts in the connecting region are connectedby contact-pressing and insert-pressing, the parts comprising an outerpipe part and two inner pipe parts, the outer pipe part having an outercollar, wherein the connection is established using three regions,wherein the connecting regions comprise press fit and stop surfaces ofthe pipe parts or press fit surfaces that cooperate with the pipe partsand collar, and that have a truncated cone shape, and that are inclinedin the end direction from the inner pipe part toward the pipe axis, andat the front comprise stop surfaces which have a truncated cone shapeand are directed counter to said press fit surfaces and a transitionthat is formed by the press fit and stop surface of the connected partsfor said parts without contact with a coaxial intermediate space orhollow space.
 2. A pipe connection assembly having a longitudinal axisalong its length and a normal axis perpendicular to the longitudinalaxis, comprising: at least one inner pipe part having a first press fitsurface, a first stop surface and a transition surface extending betweenthe first press fit surface and the first stop surface, and an outerpipe part having an interior wall, an outer collar, a second press fitsurface, a second stop surface, and an annular recess in said interiorwall encircling the longitudinal axis and extending from said secondpress fit surface and said second stop surface, the recess protrudingoutward from the longitudinal axis and extending beyond the second pressfit surface, wherein, when the outer pipe part is joined with the innerpipe part to form a connection, the connection forms three regionscomprising: a press fit region, defined by the cooperation of the firstpress fit surface and the second press fit surface, wherein the pressfit region is a lateral surface of a frustum of a right circular conewhich is inclined in the direction from the inner pipe part toward theinner pipe axis, a stop region, defined by the abutment of the firststop surface and the second stop surface, wherein said stop region is anadditional lateral surface of an additional frustum of an additionalright circular cone, the second stop surface configured counter to saidpress fit region, and a transition region extending from the press fitregion to the stop region and defined by the inner pipe part transitionsurface and the recess, said transition region forming an intermediatespace or hollow space, wherein the quotient of the length of thetransition region to the length of the press fit region is from 0.4 to1.7, wherein second press fit surface is inclined at a ratio of about1:10 relative to the diameter, wherein the first and second press fitsurfaces and/or the first and second stop surfaces feature a surfaceroughness of between Ra=3.2 μm and Ra=0.4 μm, and wherein the secondstop surface is angled from between 10° to 20°, relative to the normalaxis.
 3. The pipe connection assembly according to claim 2, wherein therecess in the transition region has no edges when viewed in crosssection.
 4. The pipe connection assembly according to claim 2, whereinthe inner pipe part is shaped in a rounded manner in the transitionregion by the press fit surface and stop surface.
 5. The pipe connectionassembly according to claim 2, wherein the recess has a transitionradius of 0.5 to 1.0 mm.
 6. The pipe connection assembly according toclaim 2, wherein the connection is for pipes with an outer diametergreater than 4½ inches, and the quotient of the length of the transitionregion to the length of the press fit region is from 0.4 to 1.2.
 7. Thepipe connection assembly according to claim 2, wherein the connection isfor pipes with an outer diameter of 4½ inches or smaller, and thequotient of the length of the transition region to the length of thepress fit region is from 0.9 to 1.7.
 8. The pipe connection assemblyaccording to claim 2, wherein the inner and outer pipe are thermallytreated or hardened at least in the connecting region and features anincreased strength.
 9. The pipe connection assembly of claim 2 whereinthe recess is corner free.
 10. The pipe connection assembly according toclaim 2, wherein the quotient of the length of the transition region tothe length of the press fit region is from 0.6 to 1.5.
 11. The pipeconnection assembly according to claim 10, wherein the quotient of thelength of the transition region to the length of the press fit region isfrom 0.6 to 1.0.
 12. The pipe connection assembly according to claim 11,wherein the quotient of the length of the transition to the length ofthe press fit region is from 1.1 to 1.5.
 13. The pipe connectionassembly according to claim 2, wherein the outer pipe part second stopsurface angle is 15° relative to the normal axis.